A novel system with positive selection for the chromosomal integration of replicative plasmid DNA in Corynebacterium glutamicum

Metabolic engineering of glucose uptake systems in Corynebacterium glutamicum for improving the efficiency of l-lysine production

Traditional amino acid producers typically exhibit the low glucose uptake rate and growth deficiency, resulting in a long fermentation time because of the accumulation of side mutations in breeding of strains. In this study, we demonstrate that the efficiency of l-lysine production in traditional l-lysine producer Corynebacterium glutamicum ZL-9 can be improved by rationally engineering glucose uptake systems. To do this, different bypasses for glucose uptake were investigated to reveal the best glucose uptake system for l-lysine production in traditional l-lysine producer. This study showed that overexpression of the key genes in PTSGlc or non-PTSGlc increased the glucose consumption, growth rate, and l-lysine production. However, increasing the function of PTSGlc in glucose uptake led to the increase of by-products, especially for plasmid-mediated expression system. Increasing the participation of non-PTSGlc in glucose utilization showed the best glucose uptake system for l-lysine production. The final strain ZL-92 with increasing the expression level of iolT1, iolT2 and ppgK could produce 201.6 ± 13.8 g/L of l-lysine with a productivity of 5.04 g/L/h and carbon yield of 0.65 g/(g glucose) in fed-batch culture. This is the first report of a rational modification of glucose uptake systems that improve the efficiency of l-lysine production through increasing the participation of non-PTSGlc in glucose utilization in traditional l-lysine producer. Similar strategies can be also used for producing other amino acids or their derivatives.

Strategies used for genetically modifying bacterial genome: site-directed mutagenesis, gene inactivation, and gene over-expression

With the availability of the whole genome sequence of Escherichia coli or Corynebacterium glutamicum, strategies for directed DNA manipulation have developed rapidly. DNA manipulation plays an important role in understanding the function of genes and in constructing novel engineering bacteria according to requirement. DNA manipulation involves modifying the autologous genes and expressing the heterogenous genes. Two alternative approaches, using electroporation linear DNA or recombinant suicide plasmid, allow a wide variety of DNA manipulation. However, the over-expression of the desired gene is generally executed via plasmid-mediation. The current review summarizes the common strategies used for genetically modifying E. coli and C. glutamicum genomes, and discusses the technical problem of multi-layered DNA manipulation. Strategies for gene over-expression via integrating into genome are proposed. This review is intended to be an accessible introduction to DNA manipulation within the bacterial genome for novices and a source of the latest experimental information for experienced investigators.

A method for simultaneous gene overexpression and inactivation in the Corynebacterium glutamicum genome

The gene integration method is an important tool to stably express desirable genes in bacteria. To avoid heavy workload and cost, we constructed a rapid and efficient method for genome modification. This method depended on a mobilizable plasmid, which contains a P tac promoter, an introduced multiple cloning site (iMCS), and rrnBT1T2 terminator. Briefly, the mobilizable plasmid pK18-MBPMT with the P tac-iMCS-rrnBT1T2 cartridge derived from pK18mobsacB was prepared to directly integrate hetero-/homologous DNA into the Corynebacterium glutamicum genome. Like our previous method, this method was based on insertional inactivation and double-crossover homologous recombination, which simultaneously achieved gene overexpression and inactivation in the genome without the use of genetic markers. Compared to the previous method, this protocol omitted the construction of a recombinant expression plasmid and clone of the target gene(s) cassette, which significantly decreased the workload, cost, and operational time. Using this method, the heterologous gene amy and the homologous gene lysC (T311I) were successfully integrated into the C. glutamicum genome at alaT and avtA loci, respectively. Moreover, the operation time of this method was shorter than that of the previous method, especially for repeated integration. This method, which is based on the mobilizable plasmid pK18-MBPMT, thus represents a potentially attractive protocol for the integration of genes in the course of genetic modification of C. glutamicum.

A method for gene amplification and simultaneous deletion in Corynebacterium glutamicum genome without any genetic markers

A method for the simultaneous replacement of a given gene by a target gene, leaving no genetic markers, has been developed. The method is based on insertional inactivation and double-crossover homologous recombination. With this method, the lysC(T311I), fbp and ddh genes were inserted into Corynebacterium glutamicum genome, and the pck, alaT and avtA genes were deleted. Mobilizable plasmids with lysC(T311I), fbp and ddh cassettes and two homologous arms on the ends of pck, alaT and avtA were constructed, and then transformed into C. glutamicum. The target-expression cassettes were inserted in the genome via the first homologous recombination, and the genetic markers were removed via the second recombination. The target-transformants were sequentially screened from kanamycin-resistance and sucrose-resistance plates. The enzyme activities of transformants were stably maintained for 30 generations under non-selective culture conditions, suggesting that the integrated cassettes in host were successfully expressed and maintained as stable chromosomal insertions in C. glutamicum. The target-transformants were used to optimize the l-lysine production, showing that the productions were strongly increased because the selected genes were closely linked to l-lysine production. In short, this method can be used to construct amino acid high-producing strains with unmarked gene amplification and simultaneous deletion in genome.

Efficient markerless gene replacement in Corynebacterium glutamicum using a new temperature-sensitive plasmid

Random chemical mutation of a Corynebacterium glutamicum-Escherichia coli shuttle vector derived from plasmid pCGR2 was done using hydroxylamine. It brought about amino acid substitutions G109D and E180K within the replicase superfamily domain of the plasmid's RepA protein and rendered the plasmid highly unstable, especially at higher incubation temperatures. Colony formation of C. glutamicum was consequently completely inhibited at 37°C but not at 25°C. G109 is a semi-conserved residue mutation which resulted in major temperature sensitivity. E180 on the other hand is not conserved even among RepA proteins of closely related C. glutamicum pCG1 family plasmids and its independent mutation caused relatively moderate plasmid instability. Nonetheless, simultaneous mutation of both residues was required to achieve temperature-sensitive colony formation. This new pCGR2-derived temperature-sensitive plasmid enabled highly efficient chromosomal integration in a variety of C. glutamicum wild-type strains, proving its usefulness in gene disruption studies. Based on this, an efficient markerless gene replacement system was demonstrated using a selection system incorporating the temperature-sensitive replicon and Bacillus subtilis sacB selection marker, a system hitherto not used in this bacterium. Single-crossover integrants were accurately selected by temperature-dependent manner and 93% of the colonies obtained by the subsequent sucrose selection were successful double-crossover recombinants.

Genes encoding ribonucleoside hydrolase 1 and 2 from Corynebacterium ammoniagenes

Two kinds of nucleoside hydrolases (NHs) encoded by rih1 and rih2 were cloned from Corynebacterium ammoniagenes using deoD- and gsk-defective Escherichia coli. Sequence analysis revealed that NH 1 was a protein of 337 aa with a deduced molecular mass of 35,892 Da, whereas NH 2 consisted of 308 aa with a calculated molecular mass of 32 310 Da. Experiments with crude extracts of IPTG-induced E. coli CGSC 6885(pTNU23) and 6885(pTNI12) indicated that the Rih1 enzyme could catalyse the hydrolysis of uridine and cytidine and showed pyrimidine-specific ribonucleoside hydrolase activity. Rih2 was able to hydrolyse both purine and pyrimidine ribonucleosides with the following order of activity -- inosine>adenosine>uridine>guanosine>xanthosine>cytidine -- and was classified in the non-specific NHs family. rih1 and rih2 deletion mutants displayed a decrease in cell growth on minimal medium supplemented with pyrimidine and purine/pyrimidine nucleosides, respectively, compared with the wild-type strain. Growth of each mutant was substantially complemented by introducing rih1 and rih2, respectively. Furthermore, disruption of both rih1 and rih2 led to the inability of the mutant to utilize purine and pyrimidine nucleosides as sole carbon source on minimal medium. These results indicated that rih1 and rih2 play major roles in the salvage pathways of nucleosides in this micro-organism.

Temperature-sensitive cloning vector for Corynebacterium glutamicum

We constructed a temperature-sensitive form of the Corynebacterium glutamicum ATCC13869 cryptic plasmid, pBL1. The C. glutamicum/Escherichia coli shuttle vector pSFK6, which is composed of pBL1 and the E. coli cloning vector pK1, was mutagenized in vitro by treatment with hydroxylamine, and introduced into C. glutamicum cells. A mutant plasmid, which was stably maintained at 25 degrees C but not at 34 degrees C, was isolated from the cells. Sequencing the plasmid, which was named p48K, revealed four substitutions in the Rep protein coding region. Moreover, site-directed single-nucleotide substitutions showed that a G to A transition at position 2,920, which resulted in a Pro-47 to Ser substitution in the Rep protein, was responsible for its temperature-sensitive replication. Pro-47 is conserved among the Rep proteins of the pIJ101/pJV1 family of plasmids. This temperature-sensitive cloning vector will be useful for disrupting genes in this industrially important bacterium.

Integration of E. coli aroG-pheA tandem genes into Corynebacterium glutamicum tyrA locus and its effect on L-phenylalanine biosynthesis

AIM: To study the effect of integration of tandem aroG-pheA genes into the tyrA locus of Corynebacterium glutamicum (C. glutamicum) on the production of L-phenylalanine.

METHODS: By nitrosoguanidine mutagenesis, five p-fluorophenylalanine (FP)-resistant mutants of C.glutamicum FP were selected. The tyrA gene encoding prephenate dehydrogenase (PDH) of C.glutamicum was amplified by polymerase chain reaction (PCR) and cloned on the plasmid pPR. Kanamycin resistance gene (Km) and the P_BF-aroG-pheA-T (GA) fragment of pGA were inserted into tyrA gene to form targeting vectors pTK and pTGAK, respectively. Then, they were transformed into C.glutamicum FP respectively by electroporation. Cultures were screened by a medium containing kanamycin and detected by PCR and phenotype analysis. The transformed strains were used for L-phenylalanine fermentation and enzyme assays.

RESULTS: Engineering strains of C.glutamicum (Tyr^-) were obtained. Compared with the original strain, the transformed strain C. glutamicum GAK was observed to have the highest elevation of L-phenylalanine production by a 1.71-fold, and 2.9-, 3.36-, and 3.0-fold in enzyme activities of chorismate mutase, prephenate dehydratase and 3-deoxy-D-arabinoheptulosonate-7-phosphate synthase, respectively.

CONCLUSION: Integration of tandem aroG-pheA genes into tyrA locus of C. glutamicum chromosome can disrupt tyrA gene and increase the yield of L-phenylalanine production.

Isolation and characterization of a rolling-circle-type plasmid from Rhodococcus erythropolis and application of the plasmid to multiple-recombinant-protein expression

We isolated, sequenced, and characterized the cryptic plasmid pRE8424 from Rhodococcus erythropolis DSM8424. Plasmid pRE8424 is a 5,987-bp circular plasmid; it carries six open reading frames and also contains cis-acting elements, specifically a single-stranded origin and a double-stranded origin, which are characteristic of rolling-circle-replication plasmids. Experiments with pRE8424 derivatives carrying a mutated single-stranded origin sequence showed that single-stranded DNA intermediates accumulated in the cells because of inefficient conversion from single-stranded DNA to double-stranded DNA. This result indicates that pRE8424 belongs to the pIJ101/pJV1 family of rolling-circle-replication plasmids. Expression vectors that are functional in several Rhodococcus species were constructed by use of the replication origin from pRE8424. We previously reported a cryptic plasmid, pRE2895, from R. erythropolis, which may replicate by a theta-type mechanism, like ColE2 plasmids. The new expression vectors originating from pRE8424 were compatible with those derived from pRE2895. Coexpression experiments with these compatible expression vectors indicated that the plasmids are suitable for the simultaneous expression of multiple recombinant proteins.

Tools for genetic engineering in the amino acid-producing bacterium Corynebacterium glutamicum

During the last decades, the gram-positive soil bacterium Corynebacterium glutamicum has been shown to be a very versatile microorganism for the large-scale fermentative production of L-amino acids. Up to now, a vast amount of techniques and tools for genetic engineering and amplification of relevant structural genes have been developed. The objectives of this study are to summarize the published literature on tools for genetic engineering in C. glutamicum and to focus on new sophisticated and highly efficient methods in the fields of DNA transfer techniques, cloning vectors, integrative genetic tools, and antibiotic-free self-cloning. This repertoire of C. glutamicum methodology provides an experimental basis for efficient genetic analyses of the recently completed genome sequence.

Amino acid production processes

With the exploitation of new uses and the growing markets of amino acids, amino acid production technology has made large progress during the latter half of the 20th century. Fermentation technology has played crucial roles in this progress, and currently the fermented amino acids represent chief products of biotechnology in both volume and value. This area is highly competitive in the world market and process economics are of primary importance. For cost-effective production, many technologies have been developed to establish high-productive fermentation and recovery processes. The producer organisms used in large-scale, well-established processes have been developed to a high level of production efficiency. The tools of genetic engineering of amino acid-producing organisms have been well developed and are now being applied for enlargement of biosynthetic and transport capacity, which is beginning to have a great impact on the amino acid industry. Furthermore, the rapid strides in genome analysis are bound to revolutionize the strain improvement methodology.

Gene replacement in mycobacteria by using incompatible plasmids

A simple and efficient delivery system was developed for making targeted gene knockouts in Mycobacterium smegmatis. This delivery system relies on the use of a pair of replicating plasmids, which are incompatible. Incompatible plasmids share elements of the same replication machinery and so compete with each other during both replication and partitioning into daughter cells. Such plasmids can be maintained together in the presence of antibiotics; however, removal of selection leads to the loss of one or both plasmids. For mutagenesis, two replicating plasmids based on pAL5000 are introduced; one of these plasmids carries a mutated allele of the targeted gene. Homologous recombination is allowed to take place, and either one or both of the vectors are lost through the pressure of incompatibility, allowing the phenotypic effects of the mutant to be studied. Several different plasmid combinations were tested to optimize loss in the absence of antibiotic selection. pAL5000 carries two replication genes (repA and repB), which act in trans, and the use of vectors that each lack one rep gene and complement each other resulted in the loss of both plasmids in M. smegmatis and Mycobacterium bovis BCG. The rate of loss was increased by the incorporation of an additional incompatibility region in one of the plasmids. To facilitate cloning when the system was used, we constructed plasmid vector pairs that allow simple addition of selection and screening genes on flexible gene cassettes. Using this system, we demonstrated that M. smegmatis pyrF mutants could be isolated at high frequency. This method should also be useful in other species in which pAL5000 replicates, including Mycobacterium tuberculosis.

Hyperproduction of tryptophan by Corynebacterium glutamicum with the modified pentose phosphate pathway

A classically derived tryptophan-producing Corynebacterium glutamicum strain was recently significantly improved both by plasmid-mediated amplification of the genes for the rate-limiting enzymes in the terminal pathways and by construction of a plasmid stabilization system so that it produced more tryptophan. This engineered strain, KY9218 carrying pKW9901, produced 50 g of tryptophan per liter from sucrose after 80 h in fed-batch cultivation without antibiotic pressure. Analysis of carbon balances showed that at the late stage of the fermentation, tryptophan yield decreased with a concomitant increase in CO2 yield, suggesting a transition in the distribution of carbon flow from aromatic biosynthesis toward the tricarboxylic acid cycle via glycolysis. To circumvent this transition by increasing the supply of erythrose 4-phosphate, a direct precursor of aromatic biosynthesis, the transketolase gene of C. glutamicum was coamplified in the engineered strain by using low- and high-copy-number plasmids which were compatible with the resident plasmid pKW9901. The presence of the gene in low copy numbers contributed to improvement of tryptophan yield, especially at the late stage, and led to accumulation of more tryptophan (57 g/liter) than did its absence, while high-copy-number amplification of the gene resulted in a tryptophan production level even lower than that resulting from the absence of the gene due to reduced growth and sugar consumption. In order to assemble all the cloned genes onto a low-copy-number plasmid, the high-copy-number origin of pKW9901 was replaced with the low-copy-number one, generating low-copy-number plasmid pSW9911, and the transketolase gene was inserted to yield pIK9960. The pSW9911-carrying producer showed almost the same fermentation profiles as the pKW9901 carrier in fed-batch cultivation without antibiotic pressure. Under the same culture conditions, however, the pIK9960 carrier achieved a final tryptophan titer of 58 g/liter, which represented a 15% enhancement over the titers achieved by the pKW9901 and pSW9911 carriers.